In high-energy physics, precise measurements rely on highly reliable detector simulations. Traditionally, these simulations involve incorporating experiment data to model detector responses and fine-tuning them. However, due to the complexity of the experiment data, tuning the simulation can be challenging. One crucial aspect for charged particle identification is the measurement of energy deposition per unit length (referred to as dE/dx). This paper proposes a data-driven dE/dx simulation method using the Normalizing Flow technique, which can learn the dE/dx distribution directly from experiment data. By employing this method, not only can the need for manual tuning of the dE/dx simulation be eliminated, but also high-precision simulation can be achieved.
@article{arxiv.2401.02692,
title = {A Data-driven dE/dx Simulation with Normalizing Flow},
author = {Wenxing Fang and Weidong Li and Xiaobin Ji and Shengsen Sun and Tong Chen and Fang Liu and Xiaoling Li and Kai Zhu and Tao Lin and Jinfa Qiu},
journal= {arXiv preprint arXiv:2401.02692},
year = {2024}
}